A method for additive manufacturing of an article having a controlled magnetic anisotropy includes: forming a metallic layer of the article using additive manufacturing, the metallic layer having a magnetic anisotropy aligned in a first direction; forming a subsequent metallic layer of the article using additive manufacturing, the subsequent metallic layer having the magnetic anisotropy aligned in a second direction different from the first direction; and repeating the forming of subsequent metallic layers of the article to form at least a portion of the article, each subsequent metallic layer having the magnetic anisotropy aligned in a different direction than a previous metallic layer

A method for measuring distance between lower end surface of heat shielding member and surface of raw material melt, the method including providing the member being located above the melt, when a silicon single crystal is pulled by the Czochralski method while a magnetic field is applied to the melt in a crucible, the method including: forming a through-hole in the member; measuring distance between the member and the melt surface, and observing position of mirror image of the through-hole with fixed point observation apparatus, the mirror image being reflected on the melt surface; then measuring a moving distance of the mirror image, and calculating distance between the member and the melt surface from a measured value and the moving distance of the mirror image, during the pulling of the crystal. The distance between the member and the melt can be precisely measured by the method.

A method for measuring distance between lower end surface of heat shielding member and surface of raw material melt, the method including providing the member being located above the melt, when a silicon single crystal is pulled by the Czochralski method while a magnetic field is applied to the melt in a crucible, the method including: forming a through-hole in the member; measuring distance between the member and the melt surface, and observing position of mirror image of the through-hole with fixed point observation apparatus, the mirror image being reflected on the melt surface; then measuring a moving distance of the mirror image, and calculating distance between the member and the melt surface from a measured value and the moving distance of the mirror image, during the pulling of the crystal. The distance between the member and the melt can be precisely measured by the method.

A feed assembly supplies polysilicon to a growth chamber for growing a crystal ingot from a melt. An example system includes a housing having support rails for receiving one of a granular tray and a chunk tray and a feed material reservoir positioned above the support rails to selectively feed one of either the granular tray or the chunk tray. A valve mechanism and pulse vibrator are also disclosed.

A feed assembly supplies polysilicon to a growth chamber for growing a crystal ingot from a melt. An example system includes a housing having support rails for receiving one of a granular tray and a chunk tray and a feed material reservoir positioned above the support rails to selectively feed one of either the granular tray or the chunk tray. A valve mechanism and pulse vibrator are also disclosed.

A silicon wafer having a BMD density of 510.sup.8/cm.sup.3 or more and 2.510.sup.10/cm.sup.3 or less in a region of 80 m to 285 M from the wafer surface when the silicon wafer is heat-treated at a temperature X ( C., 700 C.X1000 C.) for a time Y (min) and then subjected to an infrared tomography method in which the laser power is set to 50 mW and the exposure time of a detector is set to 50 msec. The time Y and the temperature X satisfy Y=7.8810.sup.67X.sup.22.5.

A silicon wafer having a BMD density of 510.sup.8/cm.sup.3 or more and 2.510.sup.10/cm.sup.3 or less in a region of 80 m to 285 M from the wafer surface when the silicon wafer is heat-treated at a temperature X ( C., 700 C.X1000 C.) for a time Y (min) and then subjected to an infrared tomography method in which the laser power is set to 50 mW and the exposure time of a detector is set to 50 msec. The time Y and the temperature X satisfy Y=7.8810.sup.67X.sup.22.5.

A feed assembly supplies polysilicon to a growth chamber for growing a crystal ingot from a melt. An example system includes a housing having support rails for receiving one of a granular tray and a chunk tray and a feed material reservoir positioned above the support rails to selectively feed one of either the granular tray or the chunk tray. A valve mechanism and pulse vibrator are also disclosed.

A feed assembly supplies polysilicon to a growth chamber for growing a crystal ingot from a melt. An example system includes a housing having support rails for receiving one of a granular tray and a chunk tray and a feed material reservoir positioned above the support rails to selectively feed one of either the granular tray or the chunk tray. A valve mechanism and pulse vibrator are also disclosed.

A method of manufacturing a silicon wafer is provided that includes extracting an n-type silicon ingot over an extraction time period from the a silicon melt comprising n-type dopants; adding p-type dopants to the silicon melt over at least part of the extraction time period, thereby compensating an n-type doping in the n-type silicon ingot by 10% to 80%; slicing the silicon ingot; forming hydrogen related donors in the silicon wafer by irradiating the silicon wafer with protons; and annealing the silicon wafer subsequent to the forming of the hydrogen related donors in the silicon wafer.